Distant accounting mechanism.



M. M. G0LDBERG. DIST/INT ACCOUNTING MECHANISM.

APPLICATION FILED APR. 1I. 1914.

Patented Jan. 4, 1916.

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M. M. GOLDBERG.

DISTANT ACCOUNTING MECHANISM.

APPLICATION FILED APR. II, 1914.

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vDISTANT ACCOUNTING MECHANISM. APPLICATION FILED APR. II. I9I4.

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DISTANT ACCOUNTING MECHANISM.

APPLICATION FILED APR. II. I9I4.'

Patented Jim. 4, 1916.

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DlsTANT ACCOUNTING MECHANISM.

APPLICATION FILED APR. 11| 1914.

Patented Jan. 4, 1916.

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APPLICATION FILED APR. II. i914'.

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M. M. GOLDBERG. l DISTANT ACCOUNTING M'ECHANISM.

APPLICATION FILED APR. II, 1914.

Patented Jan. 4, 1916.

YSHEETS-SHEEI' maximilian maldbe CI Ionncig UNITED STATES PATENT OFFICE.

MAXIMILIAI H. GOLDBERG, OF DAYTON, OHIO, ASSIGNOR TO THE NATIONAL CASH REGISTER COMPANY, OF DAYTON, OHIO, A CORPORATION OF OHIO, (INCORPORATED DISTANT ACCOUNTING MECHANISM.

Specication of Letters Patent.

Patented Jan. 4, 1916.

Application led April 11, 1914. Serial N o. 831,313.

l the following to be a. full, clear, and exact description.

This invention relates to improvementsin registering systems, in which the manipulation vof one machine which may be called the sending machine, electrically controls at a. distance the operation of another machine which, for convenience, may be called the receiving machine.

The general object of this invention is to provide an improved system of electric wiring whereby the use of av number of wires, which extend from the sending machine to the receiving machine and are suflicient for one bank of controlling contacts of the sending machine, may be employed at the same time for any number of different denominational banks of controlling contacts, each .bank of the sending machine having its own common return wire from the receiving ma.- chine so that iti may control. thel extent of movement of an element of the corresponding denomination in the receiving machine, all of these elements beingoperated simultaneously.

Heretofore/ a set of wires extending from each bank of contacts ofthe sending machine to a corresponding bank of contacts of the receiving machine has been consideredthe-minimum in vthis class of machine. The provision of one wire besides the common return wire for any number of banks of controlling contacts is also old in the art, but in the machine to which Ythis wiring is applied, the denominational elements of the receiving machine are operated successively, instead of simultaneously, as in the present invention. It is obvious that the employment ofcne set of wires for any number of bank controlling contacts, instead of one set ceiving machine, instead of a. successive op` eration, is also a very important advantage as the operation of the system requires considerably less time.

Another object of the invention is to con` struct thedifferential mechanism of the recelvi-ng machine so that it may be positively operated by the operating mechanism of the receiving machine under the control of the sending machine.

0 IV ith these and incidental objects in view, the invention consists in certain novel fea` tures of construction and combinations of parts, the essential elements of which are set forth in appended claims, and a preferred form of embodiment of which is hereinafter described with reference to the drawings which accompany and form part of the specification.

Of said drawings Figure 1 is a transverse vertical. `section taken through the sending machine. Fig. 2 is a detailed cross ,sectional view through the stationary con- Icommon horizontal contact bar as on the line X-X, Fig. l, and shows the contact strips carried by one of the manually adjustable determining levers of thesending machine. Fig. 3 is a reduced rear view of a portion of the contact making frame shown iny Fig. 2. Fig. 4 is a transverse vertical section taken near the right hand vside frame of the receiving machine and showing the mechanism thereof in normal position. Fig. 5 is a transverse vertical section taken through 'the receiving machine near its left hand side showing the totalizer" selecting mechanism in operated position. Fig. 6 is aV detailed view showing the motor locking mechanism and the motor circuit closing device, the motor being broken away for the sake of clearness. Fig. 7 is a detailed view' showing the totalizer switch and the cam for closing the same. Fig. `8 is a side elevation of the printing mechanism for the receiving machine, and shows in section the electrical magnet employed/ to control the devices shown in Fig. 6. Fig. 9 is a 'top plan view of the receiving machine with totalizers,

the contact making frame removed. Fig. 10 is a diagrammatic view of the various electric circuits and connections.

For the purpose of setting forth, in a general way, the construction of the devices which have been specifically adopted to carry out the broad objects mentioned above, it may be stated that the sending machine comprises a series of manually adjustable setting levers, one for each bank of controlling contacts, and these levers carry certain contact making devices which establish contacts between contact bars, one for each lever, andcontact bars, one for each position of adjustment of the setting levers and common to the setting levers. The common contact bar for each setting lever, and the contact points, for the particular lever on the contact bars common to the various levers, will, for the sake of convenience be called herein a bank of contacts. When the sending machine is operated by the turning of a crank handle, or other suitable means, this results in the closing of a circuit through a motor connected to the driving shaftof the receiving machine so as to operate the latter. During the operation of the receiving machine, differentially movable segmental members, called herein actuating segments, and corresponding to the setting levers of the sending machine, are positively driven by the operating mechanism of the receiving machine, and when these actuating segments reach positions corresponding to the position of the corresponding setting levers of the sending machine contacts are made to establish circuits through corresponding contact bars in the receiving machine. The making of such contacts at the receiving machine results in electric magnets being energized to stop and lock the actuating segments in positions corresponding to the differential extents of movement of the respective setting levers of the sending machme. These actuating segments of the recelving machine are designed to actuate type carriers and actuating racks for totallzers to a corresponding extent.

The receiving machine is provided with a plurality of independent totalizers which are normally out of operative position with their. actuating racks, and any one of these totahzers may be thrown into operation, as predetermined' by the position of a special counter selecting lever of the sending machlne. In the preferred form of embodiment shown in the drawings, but two totallzers are employed, but it is to be understood that itis not intended to limit the invention for actuating but twototalizers as it will be evident from the following description that any number of totalizers might be used. After a printing impression has been taken frm'the'pos'itioned -t'ype 'carriers of the r'- c'eiving machine and after the selected totale` massiv izer has been engaged with the positioned actuating racks, the actuating segments, and therefore, the racks, are restored to normal position to actuate which ever totalizer is in engagement with the racks. Provision is also made for unlocking the receiving machine from the sending machine, and the setting levers of the sending machine are automatically locked until the receiving machine has completely finished its operation.

Having described the general opera tion of the machine, the specific arrangement of the parts will now be described in detail.

Sending machina-The sending machine shown in Fig. 1 is provided with a series of manually adjustable setting elements or levers l, which are loosely mounted upon a central shaft 2 suitably supported in the side frames 3 of the machine. These levers move over any ordinary form of scale (not shown but at the right in Fig. l) on the front of the machine so as to be set differentially to any desired point, according to the amount to be registered in the receiving machine. For convenience in setting the levers l to :sov

their desired positions, numeral bearing `indicator wheels 4 are provided. Each indicator wheel is rigidly mounted upon a corresponding sleeve 5, rotatably mounted upon a transverse shaft 6, the right hand indicator wheel being fast upon this shaft. A disk 7 and pinion 8 are rigidly mounted on each of the sleeves and the shaft. The pinion 8 for each indicator wheel is arranged to constantly mesh with the teeth 9, which are arranged concentrically `about'the shaft 2, and on` the central portion of its respective setting lever, so that'whenany setting lever is adjusted its respective indicatorV moves simultaneously to indicate the position of the lever, and in this mannerassists the operator in properly adjustingthe lever to its desired position. l

In addition to the ordinary amount setting levers 1, a special counter selecting lever 10 is provided. This selecting lever'lO, as shown in Fig. 1 of thezdrawing, is similar to the amount setting levers, except thatl it has but two positions of ladjustment for selecting one or the other of--th'e two totalizers of the receiving machine for operation. and therefore, it also Vhas fewer teeth for meshing with the pinion 8 o'fits corresponding indicator wheel. It is to be understood.

of course, that the'A receiving machine-may C be supplied with any number of totalizers and that the selecting leyer 10 of the sending i (Fig. 2) which are separated from the lever'.

by an insuating Ystrip" 14,- thef'centact strips being attached to the levers by screws 15,

concentric with the contact bars .16 andy carry lugs 21 which, as shown in Fig. 1 are fastened by pins 22 to the side frames 3 of the machine. These curved rods 20 are integral with the cross bars 18. The contact bars 16 are separated froml the cross bars 18 by strips 23 of insulation, the screws 17 also being suitably insulated from the contact bars. The spring Contact 1-3 for each lever successively engages the right hand sides of the projections 24, projecting inwardlyfrom horizontal contact bars 25, which are insulated from each other by strips 28 and extend laterally across the frame 19, and at right angles. to the contact bars 16 The contact bars 25 are insulated from th'e contact bars 16 by insulating strips 26, and the ends of the contact bars 25, which are insulated from the side rods 20 of the frame by insulating strips 27, are firmly heldin place against the side rods 20 by the contact bars 16. Each of the horizontal contact bars 25 has but one wire connected thereto, and that wire extends to a corresponding Contact bar of the receiving machine as will be presently described. In the zero position of any one of the amount setting levers 1 its contact strip 13 is in Contact with the projection 24 on the top contact bar 25, which is the O contact bar for all of the levers. When the handle of any lever (which handle is at the end opposite to that bearing the spring contacts I 12 and 1.3) is pulled upward to adjust the lever to some other position, its contact strip 13 is lowered to successively contact with the projections 24 of` the various contact bars 25 common to all the levers, while the other contact strip 12 is continuously in contact with the contact bar 16 to whatever position the lever is adjusted, so that each of these contact bars 16 can be properly said to 'constitute the common for the bank of contacts for its lever. This common contact bar has attached to-it a common lead wire, so that the current furnished from a. battery or other source of electric energy upon operation of a system flows through the common contact bar 16,v spring, contact 12, spring contact 13, and then tothe particular contact bar 25, `whose projection 24 is in engagement with contact strip 13 on the particularlever and this arrangement of vthe contact bars-16 and 25 is repeated at the receiving machine, vas will be presentl'yidescribed, so that the position of the setting levers of the sending machine may control the extent of movement of the differential mechanism of the receiving machine.

In the illustrated'forin disclosed in this application the spring contact strip 12 on the special lever l0 constantly engages its common 16. vWhen the lever is in norma'L position the other contact strip 13 is in contact with one of the projections 24 on the 8 contact bar 25, and the lever is adapted to be adjusted so that its contact 13 is carried into lcontact with the 9 contact 25.

Sending 'machine locking mechanism-In order to aline the indicators 4 so that the indicating numerals will always be left in proper alinement, and for the further purpose of locking the setting levers, and the parts controlled thereby, during the operation of the sending machine, locking and alinement pawls 30 areprovided, there being one pawl for each setting lever. These pawls are bell crank in form, and are loosely mounted upon a cross shaft 31, 'which is supported by the side frames 3 of the niachine. The rear end of each pawl is provided with a wedge-shaped downwardly projecting nose 32, which coperates with a series of V-shaped alining notches 33 formed on the alining disk 7. A crossbar 34 passes over the upper edge of the rearwardly extending arms of the bell crank levers 30 and the bar is normally out of engagement, so that the bell cranks may be rocked upward by the notches 33 upon adjustment of the levers. Springs 35, connecting the downwardly extending arms of thepawls 30 and a cross rod 36, are tensioned to normally retain the noses 32 of the pawls 30 in engagement with any of the notches 33 on the disks 7. The cross bar 34 is supported at its ends by two arms 37, which are rigidly mounted near the ends of the shaft 31. Extending downwardly from shaft 31, and rigid therewith, is an arm 3S, which at its lower end ilo carries an anti-friction roller 39 for coperating with a locking disk 40 rigidly secured to a rotation shaft 41. The locking disk 40 the other end to a pin 451 projecting from the frame 3 of the machine, normally holds the roller 39 in the notch 42 of the disk 40. so that the cross bar 34 is held in elevated position above bell crank pawls 30.v As

soon, however, as the shaft 41 is rotated by i125,

a. crank handle or any suitable means (not shown), far enough `so that the solid pe` riphery of the disk 40 coperates with the i roller 39, the shaft 31 will be rocked to lower the cross bar 34 into engagement with upper edges of the-locking pawls 30 to retain the alini-ng noses 32 in engagement with the alining notches 33 until the shaft 41 has completed its rotation, when the spring 43 vwill again raise the bar 34 to normal position. From this construction, it can be seen that it is impossible to move any of the Setting levers l or 10 during the operation of the machine, the rotation shaft 41 being given one rotation at each operation.

It will be evident that the sending machine might be supplied with any desired form of registering mechanism which could be operated during the rotation of the shaft 41. In the drawings, the sending machine is not shown as being provided with printing mechanism, but it might be mentioned here that the printing mechanism for the receiving machine (shown in Fig. 8 of the drawings) is so constructed that it can be applied to the sending machine without any change whatever. In such a case, type carriers 74 of the printing mechanism for the receiving machine would be mounted on the sleeves 5 and shaft 6, and the impression means would be operated from the driving shaft 41. This printing mechanism is not shown in the drawing as attached to the sending machine, as it would necessitate the filing of an extra figure, and would not in any way add to the understanding of the invention.

In order to prevent an operation of the setting levers 1 and 10 of the sending machine before the receiving machine has completed its operation, a bell crank lever 45 is provided. This lever is mounted upon a cross rod 46, and at the upper end of its upwardly extending arm 460, carries an anti-friction roller 47, which is held in engagement with the periphery of a nearly circular cam disk 48 by a tensioned spring 49, which is connected at one end to an arm 46() of the bell crank lever, and at its opposite end to a pin 50 extending from frame 3 of the machine. The cam disk 48 is rigidly mounted on the rotation shaft 41. An electromagnet 51, supported by a bracket 52 mounted on the base 53 of the machine, is energized at the beginning of the operation of the receiving machine to draw its armature 54 forward against the tension of its spring 55, so that the upper end of the armatureis under the rearwardly extending arm 56 of the bell crank lever 45. This electromagnet is controlled by the receiving machine, as will be presently described in connection with the electric circuits, in such a manner that itis denergized only at the end of the operation of the receiving ma-` chine, and then the spring 55 drawsthe armature 54 away from under the arm 56, to permit movement; of the bell crank lever 45. From this construction it is evident that the sending machine cannot complete its operation until after the receiving machine has beneath the arm 56 of the bell crank lever,

and the armature, as stated, is not withdrawn until at the very end of the operation of the receiving machine.

Receiving machine releasing switch- Upon operation of4 the sending machine a circuit is completed through a starting coil of an electromagnet in the receiving machine to release the motor for operating the receiving machine and to close the motor circuit. The circuit and starting coil for unlocking the motor of the receiving machine will be described later, but the switch employed in the sending machine for closing the circuit through this starting coil in the receiving machine may be described here. A cam disk 60, which is fast on the drive shaft 41 (Fig. 1) acts upon an anti-friction roller 61 carried at the lower end of an arm 62 which is pivoted at 63 to the side frame 3 of the machine, so as to swing the arm forward at the beginning of the operation of the sending machine. lThis arm 62 has -an insulating block 64 attached to its lower end, and when the arm isswung forward, the block 64 presses a contact strip 65 against a contact 66 to complete a circuit through the starting coil of the receiving machine as will be presently described.

Differential 'mechanism of receiving machina-The receiving machine, as shown in cross section in Fig. 4, has loosely mounted upon a central cross shaft 70 a plurality of differentially movable actuating segments 71, corresponding to the amount setting levers 1 of the sending machine. The actuating segments are arranged to be moved positively by the driving mechanism to distances exactly corresponding to the differential movements of the amount setting levers of the sending machine so as to enter upon either of the totalizers 72 or 73, and to-set upon the type carriers 74 (Fig. 9) an amount commensurate to the value indicated by the positions of the setting lever of the sending machine. In order to control the extent of movement of these actuating segments 71 the forward end of each segment has a pair of contact strips I75 and 76 (Fig. 9) suitably insulated from the actuating segments by the insulating strips 77, and the construction of these contact strips is identical to that of the contact strips 12 and 13on the amount setting levers of 'the sending machine. The contact strip 76 is constantly pressed'against a common contactbar 78 (Figs. 4 and 5) for the bank of contacts of the particular actuating segment. The other contact strip 75 on each lever. engages one or another of a series of projections 79 on the contact bars 80, which are common to all of the actuating segments.

The contact bars 78 and 80 are constructed and arranged respectively like the contact bars 16and 25 of the sending machine, and these bars of the receiving machine are insulated from each other, and held in place on the cross bars 81 of a supporting frame 82 in the same manner as the contact bars of the sending machine are insulated from each other and secured to the cross bars 18 of the supporting frame 19. The corresponding contact `bars of the sending machine are electrically connected to those of the receiving machine, that is to say, the common 16 for the units setting lever 1 of the sending machine is connected by a common return wire to the common 7 8 for the units actuating segment of the receiving machine, and so on, and the 0 or uppermost contact bar 25 of the sending machine is connected by a single Wire to the 0 or uppermost contact bar of the receiving machine, and so on.

The receiving machine, in addition to the amount actuating segments 71, is also provided with a special selecting segment 84 (Fig. 5), which corresponds to and is controlled by the special counter selecting lever 10 of the sending machine. -The construction of this special segment 84 is similar to that of the amount actuating segments 71, except that the former has but two positions of adjustment, and is so designed that its contact strip 75 is normally in engagement with the 8 contact bar 80 and is adaptedto be moved into engagement with the 9 7 contact bar 80.

ln circuit with the corresponding commons 16 and 78 are electromagnets 86 (Figs. 4 and 5) there being one for each actuating segment 71 and one for the special segment 84, and these electromagnets are supported by brackets 87 mounted on the base 85 of the receiving machine. The armatures 88, one for each electromagnet 86, are suitably mounted on across rod 89, and are connected by springs 90 to a cross rod 91, these cross rods 89 and 91 being suitably mounted in the side frames of the receiving machine. The armatures 88 for the electromagnets nnormally support corresponding levers 92 as the armatures 'are normally drawn forward by their springs 90 so that their upper ends engage shoulder 93 formed on the levers 92. 1n the'description of the receiving `machine the direction in which the spring tends to draw the armatures 88 will be considered as the forward. direction. The levers^92 are loosely mounted upon a cross rod 94, and the levers in front of this shaft carry laterally projecting studs 95, which normally engage the upper edges of the forwardly extending fingers 96 of locking pawls 97. These locking pawls also are mounted loosely upon the cross rod 94 beside their corresponding levers 92. The fingers 96 of the pawls are connected to the lower ends of springs 98, which at their upper ends are secured to a cross rod 99, also supported by the side frames of the machine. rlhe springs 98 tend to rock the pawls 97 in a clockwise direction (as `viewed in Fig. 4), but this movement is normally prevented by the studs 95. The noses 100 formed on the upper rear ends of the locking pawls 97 are arranged to engage any one of a series of notches 101 formed on theforward ends of their corresponding amount actuating segments 71 and a special segment 84. These amount actuating segments and the special segment 84 are diven positively to extents corresponding to the ypositions of the corresponding setting levers in the sending machine by operating mechanism, to be now described. Each amount actuating segment 71 below the supporting shaft 70 (Fig. 4) is provided with gear teeth 104 normally meshing with the teeth of a segment gear 105 pivoted at 106 on the rear end of the corresponding lever 92. The special segment 84 (as shown in Fig. 5,). is also provided with gear teeth 104 which mesh with a segment gear 105, but the teeth on this segment 84 and on the segment gear 105 are fewer than those on an amount actuating segment and on a corresponding segment gear, as the special segment 84 is designed to be moved but one step from its normal position while the amount actuating segments may be moved to any one of nine positions from normal. The amount actuating segments 71, as well as the special segment 84, carry plates 108, which project beyond the gear teeth 104 to prevent lateral swinging of the rear end of the levers 92 to the left so that the segment gears 105 mounted on the levers will not slide out of mesh with the gear teeth 104.

Downwardly extending arms 109, one for each segment gear 105, are pivoted at their lower ends to the forward ends of links 110, and these links at their rear ends are loosely mounted upon a tie bar 111. The tie bar 111 `is supported at its ends by triangular shaped plates 112 (Figs. 4 and 5,) which are loosely mounted upon a cross shaft 114 suitably journaled in the side frames of the machine. The plates 112, as shown most clearly in Figs. 4 and 5, carry anti-friction rollers 116, which play in cam grooves 117, formed in the faces of disks 118, which are rigidly mounted upon a rotation shaft 119, driven in a manner to be hereinafter described. The configuration of these cam grooves 117 isf such that at the beginning of each operation of the receiving machine the tie bar 111 is carried forwardly to rotate the segment gears 105 in a clockwise direction about their pivots 106. This movement of/the segment gears 105 rotates the actuating segments 7l and the special segment 84 in the reverse direction, that is, the forward ends of the segments (at the left in Fig. 4)" are lowered. A restoring bar 121 normally engages the surfaces 122 on all of the segments71'and 84 and the bar is supported at the forward ends of arms 123 fast on the -shaft 114, which is rocked in a manner to be presently described at the beginning of each operation of the machine to elevate the restoring bar 121 and thereby permit movement of the segments.

As soon as thecontact strip on any one ofthe amount actuating segments 71 reaches' a projection 7 9- on the Contact bar 80, which correspondsto that contact bar 25 of the sending machine which is engaged by the contact strip l13 of the corresponding setting lever f1, an electric circuit is completed from a source of electric energy, through the common 78 for the segment,

common 16 for the corresponding setting lever, these corresponding contact bars 25 and 80, and through the electromagnet 86 for the segment. yThereupon the armature 88 of the energized electromagnet 86 for the particular actuating segment is drawn rearward out of'engagement with the shoulder 93 on the lever 92, so that the rear end of the lever 92 may drop downward to disengage its segment gear 105 fromthe teeth 104 of the actuating segment 71. At the same time the spring 98 forces the upper end of the locking pawl 97 rearwardly, the stud having been raised by the downward movement of the rear end of the lever 92, and hence the nose 100 of the paw'l engages the notch 101 which has beenv brought lopposite thenose oftthe pawl, and in this manner the movement of the actuating segment 71 is arrested at the 4same time that its driving segment gear is disengaged from the gear teeth 104, the segment gear being permitted to continue its rotation after such disengagement. 1t is evident that the special segment 84 has a similar operation, only the special segment 84 is vadapted to receive but one movement from normal position. 1f an `amount setting lever 1 or the special counter selecting lever 10 of the sending machine has not been adjusted out of its home position, a circuit will be completed through ,the corresponding electromagnet 86 in the receiving machine before the segment gear 105 controlled by the magnet, begins its rotation, so that the corresponding locking pawl 97 may be moved tolock the corresponding actuating segment 71 or special segment-84l against movement, and the segment gear 105 at the same time drops outof engagement with gear teeth 104 on the vparticular segment which has not .been moved out of home position.v Y A shaft extends across the'machine below the rear end of levers 92, and forms a stop for the levers when they are lowered to disengage the segment gears 105 from the teeth 104 on the segments 71 and 84. 70 While the actuating segments 71 and the special segment 84 are in their set positions a printing impression is made by the printing mechanism, as will be later described, and then the segments 71 and 84 and the 75 segment gears 105 are restored to their normal positions shown in Fig. 4. To' accomplish this restoration the locking pawls 97 are first rocked back to normal position so that their noses 100 are carried, out of en- 80 gagement with the notches 101 in the segments 71v and 84. rlhe segments are then returned to their normal or zero position, and finally the segment gears 105 are elevated into engagement with the gear teeth g5 104, these segment gears 105 having been rocked back in normal position relative to the carrying levers 92 by the cam grooves 117 before this normal engagement is effected. A cross rod 132 passes under the'go rearwardly extending fingers 133 of the l locking pawls 97 and this bar is supported at the forward ends of two arms 134 rigidly mounted on shaft 130. rlihe rearwardly eX- tending arm 135 of one of the arms 134 95' carries at its rear end an antifriction roller 136' which rides on the periphery of a cam disk 137 (Fig. 4) rigidly mounted on the shaft 119. The construction of this cam disk is such that after the printing mecha- 100 nism, has been operated to take a printing impression, the roller will be forced downward, as it passes into engagement with the circular portion 138 of the cam periphery, to rock shaft 130, so that the cross" rod 132 105 Owill be elevated to rock the pawls 9,7 out of engagement with notches 101, but this cross bar is not elevated at this time sufliciently to elevate the levers 92 to normal position. The segments 71 and 84 are then restored to 11') normal position by the lrestoring bar 121 which is operated in thef following manner. rllhe righthand arm 123, supporting the restoring bar 121, carries a roller 139 as shown in Fig. 4, and this roller engages in a cam' 115 groove 140 formed in a disk 141 mounted'I on a shaft 142, which is given one complete rotation at each operation of the machine, as will be presently described. r1`he cam groove 140 is so designed that the restoringl 120 bar 121 is raised at the beginning of each operation of the receiving machine to permit movementv of the segments 71 and 84, and after the noses 100 of the pawls 97 Vare disengaged from the notches 101 in the seg- 125' mal position. After these segments 71 and 1? o ,have been rocked rearward to normal position, again mesh with the gear teeth 104 of their corresponding actuatingsegments 71 and special segment 84. It is evident that movement of the segments 71 and 84 from adjusted position breaks the electric circuits `through the corresponding commons 16 and 78 or" the receiving and sending machines, but as a circuit through the 0 contact bars 25 and 80 and the corresponding lcommons 16 and 78 cannot be broken in this manner when a segment 71 or l84 is not moved from normal position, this restoration of the segment gears 105 into engagement with the gear teeth 104 is not effected until near the very end of the operation of the machines, and after a switch'which is to be described later and which is in these circuits, has beenbroken so that the armatures 88 may be drawn forward to normal position by their springs 90 to bring them under the shoulders 93 of the levers 92.

Totclz'acr mecumz'sm.-Ea-ch of the amount actuating segments 71 is provided with a segmental portion 151 which carries teeth 152 constantly meshing with the teeth of a corresponding pinionh153. r.lhe special segment 84 is also provided with a segmental portion 150 (Fig. 5) which is similar to the segmental portions on the amount actuating segments except that' it has fewer teeth which mesh with a corresponding pinion 153. @ne of these pinions 153 is rigidly mounted upon a shaft 154, while the remaining pinions are fast to the concentric sleeves 155 mounted to rotate about the shaft 154 f (Fig. 5). This shaft and the sleeves 155 carry on their opposite ends the type Vcarriers 74 of the printing mechanism, which is shown in Figs. 8 and 9 and will be described later. The shaft and these sleeves carry alining disks 156 which are similar to ythe alining disks 7 of the sending machine. The bell crank levers 157, loosely mounted4 on a. shaft 158 are also similar to the bell crank levers 30 of the sending machine, and their downwardly extending noses coperate with thealining notches 160 in the disks 156 to aline them in the proper positions, the springs 161 which connect the downwardly extending arms of the levers -157 .to a cross rod 169 being provided to lforce .the noses in thev notches. j

The receiving machine has mounted in vrsuitable' guide bars 162, extending across 'i the top of the machine, a series of rack bars j i, 163, and each bar has a set of teeth 164 on its downwardly projecting portion 165, and

the teeth mesh with a corresponding pinion 153. It can, therefore, be readily seen that these racks are arranged `to be moved rearwardly by the actuating segments 71v to the same extent as the corresponding amount lsetting levers of ythe sending machine. A rack bar is not provided for the special seg- 'ment 84, as this segment is only employed to select one of the totalizers 72 or 73 (Fig. 4) for operation, and to set up a special type carrier 166 (Eig. 9). Each of these amount racks 163 has on its upper surface two sets of rack teeth 167 and 168, the set of teeth 167 being arranged to actuate a totalizer 72 (Fig. 4), which will be called totalizer No. 2, and the other set of teeth 168 is arranged to actuate the other totalizer 73, which will be called N o. 1. After the racks 163 have neen set and the printing impression has been taken from the type carriers, the particular one of these totalizers, which it is desired to operate, is low` ered into mesh with its corresponding rack teeth so as to be operated during the restoring movement of the rack barsv to normal position, which is effected by restoring bar 121 as has been already described.

The totalizers No. 1 and No. 2, and the method of rocking them into engagement with their sets of corresponding teeth 167 or 168 will now be described. The totalizer wheels 170 of each totalizer are loosely mounted upon a corresponding'shaft 171, which extends across the racks 163 and is carried by the totalizer frame, comprising side plates 172 (Fig. 5) mounted to rock upon one of the rods 173, which are supported by the side frames of the machine. The left hand side plate 172 of each totalizer frame has a downwardly extending arm 174 which carries a pin 175, to which one end of a tensioned spring 176 is attached, the opposite endp the spring being secured to a pin 177 on a. trip pawl 178. These pawls 178, one for each totalizer, are pivoted at 179 to the side plates 172 of their totalizer frames, and each has a shoulder 180, which normally engages the under side of the totalizer shaft 171 to hold the totalizer wheels out of engagement with their set of rack teeth' on the rack bars 163. The totalizer frame for totalizer No. 2 is shown in nor-- rlhe electromagnets 183, there being one for each totalizer, are mounted in the brackets 184, and lthe springs 185, which connect the .armatures 182 with the pins 186 projecting from the brackets 184, normally retain the armatures in engagement with the shoulders 181 on the trip pawls 178. The side plate 172 of each totalizer frame is also equipped with a roller 187 which normally rests on a reciprocatory restoring bar 188, mountedupon the guide bars 162, and these rollers are provided to act as stops so that lthe springs 17 6 cannot elevate the totalizers 1t is clear from this construction that thel spring 176 will pull the released trip pawl down into engagement with a pin 189 on the restoring bar 188 faster than the force of gravity will draw the totalizer frame downward. When one of the pawls 17 8 is-pulled downward in this manner, the bar 188 is in normal position, and in this position of the bar, the pin 189 is out of the path of movement of the shoulder 190 on the pawl so that the pawl may be pulled downward until its finger 191 engages the pin 189. As soon as one of the pawls has been pulled downward, the restoring bar 188 is moved slightly rear- Ward to the position shown in Fig. 5. 1t can be seen from this figure that when the restoring bar 188 is moved to this position, one of the pins 189 will engage the vertical face of the shoulder 190 of the trip pawl 178 which Vhas been drawn downward and bodily move the pawl rearward, in this manner rocking the totalizer frame about its shaft 173 to insure the engagement of the totalizer wheels with their set of corresponding rack teeth on the rack bars 163, before the restoring movement of the rack bar has begun. 1t might be well to note here that the trip pawls 17 8 could be dispensed with, and that the side plates 172 could be provided with projections similar to the downwardly extending arms of the trip pawls. The armatures 182 would then be arranged to coperate directly with these projections, and when an armature was drawn downward a spring could be employed to pull the selected totalizer into- 'mesh with the actuating racks. rllhe present construction disclosed herein is preferable, however, as the armatures 182 are required to hold the totalizers out of mesh with their actuating racks only against the force of gravity, whereas if the trip pawls 178 were dispensed with, the armatures would have to support the totalizers against the action of their springs, as well as against the force of gravity. A

The arrangement of the circuits for energizing these electromagnets 183 will be describedl in connection with the diagrammatic view of the circuits, but it may be well to state here that when the special lever 10 of the sending machine is in sucn position that its contact strips 13 engages with 8 contact bar 25, that is, the second vContact bar from the bottom, the electromagnet 183 for totalizer N o. 1 will be energized during operation of the sending machine, a circuit being completed from the battery or other source of electric energy through the common 78 for the special segment, a contact block 195, (see Figs. 4 and 5) electromagnet 183 for totalizer No. 1, and then back to the battery. When the setting lever 10 of the sending machine is in its other position ofl adjustment, that is, when the contact strip 13 is in engagement with the 9 contact bar 25, the special segment 84 of the receiving machine is moved to a like position, and then during the operation of the receiving machine a circuit is closed from the battery through the common 78, a contact block 196, electromagnet 183 for totalizer No. 2, and then back to the battery.` The contacts 195 and 196 are small square blocks of conducting material, which are suitably mounted on the common 78 for the special segment so that their right hand side faces are flush with the right hand side of the common 7 8, and these contact bars are insulated from each other and from this common 78. The contact strip 76 on the special segment 84 is so shaped (Fig. 9) as to be constantly in engagement with the common 78 and normally in engagement with the contact 195. Upon movement of the special segment to the lower of its `two positions the contact strip 76 is carried into engagement with the contact block 196. r1`he purpose of providing these eXtra contacts 195 and 196 will be described in connectionwith the circuits. 1t is only necessary to close these circuits through the electromagnets 183 for a time sutlicient to permit the armatures 182 to be pulled downward, but it is essential that these circuits be closed while the printing impression is being taken and before restoration of the special segment 84'is begun, for if this segment has been moved to its lower position,l the No. 2 totalizer would be selected for operation land then when th j segment was restored to normal positieV a circuit would be made through the electromagnet 183 for the-No. 1 totalizer, and, of course, it lis essential that such an operation should not take place. Furthermore, it is evident that the electromagnets should be denergized so that their armatures may engage with their trip pawls 17 8 when these pawls are restored to normal position, so that the totalizers will be held out of mesh while the restoring bar 188 is moved back to its normal position. r1`oavoid these dificulties a switch is provided for these totalizer magnet circuits, and this switch may, for convenience, be referred to as the totalizer switch, and its position in the circuits will be explained more definitely in connection with the varinet 183 is again energized at another ation of the machine.

ous circuits. The mechanical construction of this switch is shown in Fig. 7. The cam disk 206 is rigidly mounted upon the rotation shaft 142, and th'e periphery of the disk coperates with the roller 207, carried by switch arm 208, loosely mounted on the cross rod 158. The arm 208 carries an insulating strip 209 which presses upon a contact strip 210, beside which are two other contact strips 211 and 212 suitably insulated from each other, and from the strip 210. After the actuating' racks 163 have been positioned and before the restoring movement is begun, the disk- 206 causes the arm 208 to press all three contact strips 210, 211 and 212 together for an instant and before the racks have begun their return movement. These contact strips have conducting wires attached to them to complete the circuits to the electromagnets 183, as will-be explained more fully in connection with the diagrammatic view of Fig. 10.

The operated totalizer isrestored to normal position out of engagement with the iack bars 163 by means of the restoring bar 188 in 4a manner now to be described. The bar 188 is recipi'ocated at each operation of the machine by a iock lever 214, which is loosely mounted on the shaft 142. At its lower end, the lever 214 Carries an antifiiction roller 4215, which plays in a cam groove 216 (shown in dotted lines in Fig. 5) formed in the face of a disk 217 rigidly mounted on the shaft 119. t its upper end the lever 214 carries a pin 218, which works in a slot 219 formed in the restoring bar 188. The cam groove 216 is so designed that the bar 188 is first moved rearward` to rock the selected totalizer into engagement with the actuating racks, as has been described above, and after the selected totalizer has been actuated, the restoring bar188 is carried back forward past its normal position. Upon this forward movement of the bar a stud 220 projecting laterally from the bar engages the edge of the downwardly extending ai'm of the trip pawl 178 and thereby rocks the forward end of the pawl upward to carry the totalizer back to normal position out of engagement with the actuating racks. Before the bar 188 is given this forward movement by the lever 214 the electroinagnet 183 for the operated totalizer is denergized, the shape of the disk 206 being such that the circuit through the magnet is broken before this movement of the bar is begun. Therefore, when the displaced pawl 178 is moved back to normal position, the spring 185 raises the forward end of the armature 182 into an engagement with shoulder 181 on the pawl to holdthe totalizer out of engagement with the actuating racks 163 until its electromagoper- Transfer mechanisms for the totalizers are v chine.

not shown in the drawings as any of the well known forms of transfer mechanism may be employed.

Printing mechanism-The printing mechanism of the receiving machine is shown in Figs. 8 and 9, and as already explained above, a duplicate of this printing mechanism can be employed in the sending ma- In Fig. 9 the inking ribbon is removed to expose the type carriers 74 and 166 to view. The amount type carriers 74 and the special type carriers 166, are set to extents corresponding to the positions of the setting levers 1 and 10 of the sending machine by the movement of their correspondiiig segments 71 and 84 of the receiving machine, as has already been fully described. These type carriers are adapted to print upon a check strip 222, which is fed from a supply roll 223 then under the roller 224, through the guide 225 between coperating feed disks 226 and 227, between the platen 228 andthe type carriers, and then through the chute 229 and opening (not shown) in the cabinet of the machine. The feed disks 226 are rigidly mounted on the shaft 142 and coperate with the two feed disks 227 which laie fast on a sleeve 234 rotatably mounted on a i'od 232 carried by the side plates 233 of the printer frame. rillie shaft 142 near the left hand side plate 233 carries a gear 248 meshing with a gear 249 fast on the sleeve 234 so that upon each complete rotation of the shaft 142, the feed disks 226 and 227 will be given one rotation to feed the paper strip.

r1`he platen 228 is carried by aplaten arm 221 fast 'to a hub or sleeve 238 which is mounted on a cross rod 239, supported by the side plate 233 of the printer frame. A cam 235 is formed on the sleeve 234 to operate with the platen arm 221 upon rotation of the sleeve. rlfhe cam 235 coperates with a projection 236 on the platen arm 221 to cause the arm to be rocked rearward and thereby gradually tension a spring 237 connecting the platen arm to a stud 238 projecting from the side frame of the machine. The cam 235 is so arranged on the sleeve 23.4 that after the type carriers have been posi! tioned, and before their restoring movement' is begun, the point on the periphery of the cam, which is the greatest distance from the axis of the rod 232 will pass out of engagement with the projection 236 on the platen arm to permit the spring 237 to draw the platen arm downward, whereby the platen 228 carries the check strip 222 against the type carriers to take an impression therefrom.

The inking ribbon 240 is of a continuous type and passes over the guide rollers 241, loosely mounted on cross rods 242, which are suitably mounted in the side plates 233 of the printer frame. A Geneva stop 243 is rigid with one of these rollers 241, and this Geneva stop is designed to coperate with the two teeth 245 formed on a disk 244 which is fast on the shaft 142. One of the curved portions 246 between the teeth 247 on the Geneva stop 243 normally engages the periphery of the disk 244, but near the end of the sending machine may now be described.

Situated on the left hand side of the receiving machine is an electro magnet 251 (Fig.

8), the armature-252 of which is piV-oted at its upper end to an arm 254 of a bell crank lever 255, loosely mounted on 'a rod 256 projecting from the side frame of the machine. On the free end of the downwardly extending arm 257 of the bell crank 255 is a pin 258, upon which rests a shoulder 259 formed on the outer end of a contact making arm 260, which is fast to the left hand end of the shaft 70. A spring 261 which is secured at its upper end to the arm 260, and at its lower end to a pin 262 projecting from the side frame of the machine is under tension and normally tends to drawlthe arm- 260 downward to rock the shaft 70.] A, spring 263 which is connected at its opposite ends.

to the arm 257 of the bell crank 255 and to the side frame of the machine, normally holds the bell crank 255 and the armature 252 in the positionshown in Fig. l8, so that the pin 258 is normally in engagement with the shoulder 259 on the arm 260, and this engagement normally prevents kthe spring 261 from drawing. the arm 260 downward. The electro magnet 251 when energized raises its armature 252 to rock the bell crank 255 against the tension of the spring 263, whereby the pin 258. is carried away from the shoulder 259 on the arm 260 to permit the spring 261 to draw the arm 260downward for the purpose of rocking the shaft 70. 'llhe closing of the circuit through lthis electro magnet 251 is -e'ected upon operation 4 of the sending machine by the bringin of the contact strip (lBigLl), in the sen ing machine, into contactwith the 'Contact block 66 this being accomplished bythe ycani 60 through the arm 62, as hereinbefore fully described. This circuit will be more fully dethe circuits of the system.- f

scribed in connection with the description of The arm v260 carries an insulating strip* 265, and when ythe arm 260 1s rocked down ward by its spring 261, the strip 265 presses the'upper contact strip 266 (Fig. 6)l of'a switch against the lower contact stri 267, and these contact strips are in circuit vwith the battery, which, in the illustrated fo-rm shown herein, is a source of electric energy between the banks of contacts ofthe sending and receiving machines.- It is necessary to have this switch in circuit with the contact bars offthebreceiving and sending Inachine so that circuits will not be completed through the .0 contact bar 25 of the sending machine` and the 0 contact'bar 80 of the receiving machine when the system is not in operation. \A closed circuit would 'evidently be established between these 0 contact bars of the two machines whenever one or more setting levers of the sending machine were in zero position', as the amount actuating 'segments of the receiving machine are normally in zero position. "The estab lishment of a contact between the two conbythe electromagnet'511under' thearm 56 of the bell crank 45 yllihentliearmature 54 is in thsfposition,-therotation'o-f shaft 41'of fthe sending machine cannot kbe completed,

as the projection'57 onthe disk`48 cannot' pass the roller 47 untilfthe armature 54 is moved awav from under the arm 56, as has been described in connection with the lsending machine. j

The motor is not showninthe drawing as its showing is not necessary' to theunderstanding lof the invention, and' anyv one of the"well known forms canbereadily vemployed. A top plan' view of themotor clutch, however, is shown in Figi; 9. rlfhis clutch is of a well known type, and will be described but briefly' here. wheel 269 is rigidly mounted on a sleeve 270' (Figs.l 6 andv 8) rotatably'mounted on the right hand end of the rotation shaft 142. A disk 271 is loosely, mounted on the sleeve 270 and the sleeve carries fast thereon a clutchinember which is not shown infthe mountedon the shaft 70'is an arm 274 (Figi 6) which is provided with la projectingpon' tion 275 for engaginga block 276` on the ldisk 271 and shoulders on. two 'disks' 278.

lVhen the shaft 7 0 is rocked -i'nthemanner v described vabove the projecting portion v27 5 is carried laway from' engagement withthe disks 271 and278.v '.-Relative movement .be

tween the `disks 2.7 8 is effected by'a spring A small gear' (not shown) to connect the-clut'chmembers 'toge'ther, so that whenl the: 'clutch member 272 is rotated by the armatpre of the rhetor,J the. gear wheel 269wi1l alsobe rotated. Th

is given three rotations to give one complete rotation to the gear wheel 280 and shaft 119. The shaft 119 also carries fast thereon a gear wheel 281, which meshes with a gear wheel 282, which is of the same size as the gear wheel 281 and fast upon the shaft 142, and in this manner one complete rotation of the shaft 119 effects one complete rotation of the shaft 142.

The disk 271, as shown in Fig. 6, is provided with a notch 283, in which a roller 284 on an arm 285 normally rests. The arm 285 is pivoted upon a. stud 286, and is fast to a forwardly extending arm 287. When the projecting portion 275 of the arm 274 is rocked out of engagement with the block 276 on the disk 271, a coiled spring 288 (Fig. 9) gives the disk a slight movement about the sleeve 270, and the roller 284 is thereby forced out of the notch 283 in the disk to lower the free end of the arm 287. This free end of the arm 287 extends ovez` ay roller 290, mounted upon an arm 291, which is pivoted at 292 to the top of the motor. lating block 293, which extends over a contact strip 294, and when the arm 287 is swung downward as described, it engages the roller 290 to swing the arm 291 downward thereby pressing the contact strip 294 into engagement with contact screws 295 to complete a circuit through the electric motor of the receiving machine for the purpose of operating the latter. This contact between the contact strip 294 and the contactscrews 295 is continuously maintained until the shaft 119 has almost completed its rotation. A nose 296 on a. disk 297, which is rigidly secured to the shaft 119 then engages a roller 298 on the lower end of an arm 299a fast to the shaft to rock the shaft 70 back to normal position. Thereupon the projecting portion 275 of arm 274 will again be in the path of the block 276 on the disks 271 and the shoulders on the disks 278. Movement of the disk 271 in this manner will be arrested, and as the notch 283 is then opposite the roller 284, the spring vco-ntact 294 raises the arm 291 and again seats. the roller in the notch 283, and in this way the circuit through the electric motor is broken. The shaft 142 then moves slightly farther to complete its rotation, and the engagement of the projecting portion 275 of the arm. 274 with shoulders on the disks 278 disconnects the clutch members. of the shaft 70 to normal position also raises the arm 260 to permit the contact strip 266 to rise out of con-tact with the contact strip 267, so that the electrical connections be- The arm 291 also carries an insu` The rocking tween the banks of contacts of the sending and receiving machines may be broken.

Electric ca'rcuz'ls Cmd cmmeczons-Hav ing now described the -main mechanical features comprising the sending and receiving machines, the various arrangements of the electric circuits and relay devices for controlling the manipulation of the system will now be described with specific' reference to the diagrammatic view, shown in Fig. 10. In this view, the sending and receiving machines are both represented diagrammatically being separated by the dot-dash line 300, the machine to the left being the sending machine, and the machine to the right the receiving machine. The main source of electric energy for supplying current to the various circuits extending between the sending and receiving machines is shown as a battery 299 stationed at the receiving machine. Upon adjustment of any of the amount setting levers 1, or the special lever 10 to the desired positions, preparatory to the operation of the system, its pair of spring contacts 12 and 13 bridges across a connection between the com` mon 16 for the particular lever, and one of the contact bars 25, common for all the le vers. This diagrammatic.view shows but two banks of contacts for two amount levers, and the corresponding banks of contacts in the receiving machine as the otherl amount banks of contacts are but a repetition of this arrangement. The bank of contacts for the special setting lever 10 of the sending machine, and the bank of contacts for the special segment 84 of the receiving machine, are also shown in this view. As described in connection with the sending machine, the spring contacts 13 of all of the setting levers of the sending machine are adapted to make contacts with the horizontal contact bars 25, which are strips of conducting material common to all of the levers, but as these contact bars 25 cannot be conveniently shown as strips in the diagrammatical view, the contact projections 24 of the bars are shown as being connected to the single set of wires 301 by the wires 302. The corre` sponding contact projections 79 of the cont-act bars 80 in the receiving machine are also shown as being connected by wires 303 to the wires 301. In reality, the wires 301 are connected directly to one end of the contact bars 25 and extend to the receiving machine where they are connected to one end of the corresponding contact bars 80.

After the setting levers of the sending machine have been adjusted to their desired positions. the shaft 41 is rotated in anv de` sired manner to operate the machine. This, as above described in connection with Fig. 1 effects, through the cam 60, the pressing together of the contacts 65 and 66, The bringing of these two contacts together results in making a circuit as follows: from vgenerator 299 through wire 304, wire 305, contact 65, contact 66, wire 306 through the solenoid starting magnet 251, wire 307, wire 307% wire 308 back to the generator 299.

' The closing of this circuit through the starting magnet 251, as above explained in connection with Figs. 6 and 8, raises the armai bringing ofv these two contacts together segment.

closes a circuit from the batte 299 through wire 310, motor 311, contact 294, contact 295, and through wire 312 back to the source of electric energy. v v

The downward movement of the arm 260, upon being released by movement of the armature 252 of the energized starting coil 251 also presses the contact strips 266 and 267 together, and this establishes an electrical connection between the battery 299 and the locking magnet 51 of the sending machine for preventing a complete operation of the sending machine before the receiving .machine has completed its operation. Starting again from the battery 299, it will be seen that this circuit extends from the battery 299 through wire 304, wire 305, wire 314, locking magnet 51, wire 315, wire 315g,

contact 266, contact 267, wire 316, wire 308,

back tothe battery. The energizing of the magnet 51 results the movement of its armature 54 under the 4arm 56 of the bell crank 45 to prevent"the projection 57 on the disk 48 from passing the'roller 47 on the bell crank `45 until theci'rcuit is broken by the restoration of the arm 260 to normal position, vwhich is accomplished by the cam 297, as described in connection with Fig. 6.

The battery 299 also furnishes the source of energy for the circuits between the banks of contacts of the -receiving and sending machines, and these connections between the bank of contacts will be traced by way of an example. If an amount setting lever `1 isl adjusted to its 9 position, a contact is established Aby means of the contact strips 12 and 13 between the 9 contact bar 25 and the `:ommon 16 for that particular lever. When the corresponding actuating segment 71 of thereceiving machine reaches its 9 position, a `contact is made across the 9 contact bar 80,l andthe common 78 for the This results in a circuit being made as follows: yfrom the battery 299, through the wire 304, wire 317, wire 318, common 78, 9 contact bar 80 (which in adiagrammatic view is represented bythe projection 79 and wire 303), wire 301, 9 contact bar 25, (represented by a projection 24 and a wire 302) common 16, common return wire 319, electromagnet 86, wire320, wire 321,.wire 315s, contact 266, contact 267, wire 316, wire 308 back to the battery.) The closing of this circuit energizes the electromagnet 86 to operate the locking pawl 97, for the purpose of stopping and locking the actuating segment in its position, and to effect a disengagement of the driving segment gear 105 from its teeth 104 on 'the actuating segment. These contacts 266 and 267 constitute switch terminals ,for the commons 16 and 78 of the sending and receiving machines, and are broken by the restoration 0f the arm 260 to normalposition near the very end of the 'operation of the receiving machine, as already described. The various circuits through any lof the corresponding banks of contacts are similar to that just described, and it is considered unnecessary to give any further example. As a common return wire 319 for eachy bank of contacts of the sending machine is provided it! is obvious from this arrangement of the elec` tric wiring that each bank/of contacts of the sending machine can onlyy control the actuating segment for the corresponding bank of contacts in the receiving machine, although the common wires 301 may be used simultaneously by diderent banks of contacts.

In the diagrammatic view, only the contact points of the 8 and 9contact bars 25 for the special setting lever 10 of the sending machine are shown, as this lever is adapted to be adjusted to only these positions. The corresponding contact points of the 8 and 9 Contact bars 80 of the receiving machine are similarly shown in this view. As the circuits, which are'established between these contact bars and the commons 16 and 78 for the setting lever 10 and special segment`81, are similar to the circuits established through the corresponding amount banks of contacts, these circuits will not be described in detail.

Circuits through the electromagnets 183 which normally hold the totalizers N o. 1 and No. 2 out of engagement' with the actuating racks may now be described. AWhen the contact strip 75 on the special segment 84 remains in contact with the-8 contact bar 80, corresponding to the position of the special lever 10 of the sending machine, a contact is made by the contact strip 76 between the common 78 for the special segment and the contact block 195. A circuit is then completed through the-electromagnet 183 for the No. 1 totalizer, this circuit being made as follows: from the battery through wire 304, wire 317, wire 326, wire 328, common 78, contact 195, wire 322, electromagnet 183 for the No. 1 totalizer, wire 323, contact 212, contact 211, contact 210, wire 324, wire 325, wire 325, wire 321, wire 315, contact 266, contact 267, wire 316, wire 308, back to the battery. To select totalizer No. 2, the special segment 84 is moved under control of the special lever 10 of the sending machine so that its contact strip 76 engages the common 78 for this segment and the contact 196, a circuit thereby being completed as follows: from battery 299, through Wire 304,*wire 317, wire 326, wire 328, common 78, contact 196, wire 327, 328, electromagnet 183 for totalizer No. 2, wire 329, contact 211, contact 210, wire 324, wire 325, wire 3253, wire 321, wire 315, contact 266, contact 267, wire 316, wire 308, back vto the battery.

The totalizer switch, comprising thetliree contact strips 210, 211 and 212, as already described in reference with Fig. 7 is closed by the cam 206 after the segment gears 105 have completed their counter-clockwise movement. vThe switch is closed but for a short time, so that the armature 182 oi. the electromagnet, which was energized, may be raised vby its spring 185 into engagement with the shoulder 181 of the displaced pawl 178 when the pawl is restored to normal position by the bar 188, so that the operated totalizer will be held out of engagement with the actuating racks until selected for operation at another operation of the system.

The purpose of providing the contact blocks 195 and 196 and connecting the Wires 322 and 327 respectively thereto instead of connecting these Wires to the 8 and 9 contact bars 80, will now be evident yin view of the above described circuits. If the Wires 322 and 327 were connected to these 8 and 9 contact bars 80 the circuits through the eleetromagnets 183 would be controlled by any of the amount setting levers when any one of these levers is moved to its 8 or 9 position and therefore if any one of these amount setting levers is adjusted so that its contact strip 13 is in engagement with either the 8? or 9 contact bar 25 and the Acontact strip 13 on the special lever is in engagement with the other one of these contact bars, circuits would be complete through both of the electromagnets 183 and both -totalizers would be operated. To make this clearerthese circuits, which 'might-be established at the same time through the electromagnets if the contacts 195 and 196 were not provided, may be tracedin the diagrammatic view. vIf one of the amount levers was adjusted to its 9 position then a circuit would be completed as follows: from the battery, throu h wire 304', wire 317, -wire 318, common 78 or the amount actuating segment; 71, corresponding to the particular amount, lever adjusted to its 9 position, i

9 contact 80, w1re327 (if this wire as connected to the 9 contact bar 80 as sumed in this example) electromagnet 183 for totalizer No. 2, Wire 329, contact 2'1'1, contact 210, wire 324, wire 325, wire 321, wire 315, contact 266, contact 267, wire 316, wire 308, back to the battery. Now if the special lever 10 has been left in its normalV position, that is, so that its contact strip 75 engages the 8 contact bar 80, a circuit through the electromagnet 183 for totalizer No. 1 would be identical to the circuit for this electromagnet described above as passing through the contact 196 except that this circuit would pass directly through the wire 322 from the 8 contact bar 80, if thiswire was connected to this bar. It can therefore be seen that if the wires 322 and 327 were connected directly to the 8 and 9 .con-

tact bars 80. the amount levers of the sending machine would control the energizing of the magnets 183 for the totalizers, whereas it is intended that only the special lever 10 should control these electromagnets. By providing the contact blocks 195 and 196 only the special lever of the sending machine controls these electromagnets as a circuit through either one of these contact blocks (and therefore through either of the electromagnets) can be established only when the contact strip 76 of the special `segment 84 is in engagement therewith, and the position of the special segment is controlled only by the special lever .of the sending machine.

While the' form of mechanim herein shown and described is admirably ,adapted to fulfil the objects primarily stated, it is to be understood that it is not intended to confine the inventio-n to the one form of embodiment herein shown and described, ask it is susceptible of embodiment in various forms, all coming within thescope of the claims which follow.

W'hat is claimed is:

1. In a machine of the class described, the combination with an accounting device; of an actuator for operating the same; a driving member for said actuator normally connected thereto; a I magnet mounted independently of said actuator for disconnecting said driving member from said actuator after the actuatorhas been moved to any delbeen moved to any desired position; aprojection operable to stop said actuator inIitSv desired position and controlled by. said magnet; and means for energlzing saidmagnet. 

